# Non Isolated POL DC/DC Converter, Module, 2.46 W, 600 mV, 4.1 V, 600 mA
**URL**: https://novapart.co/products/RPZ-0.6-CT/non-isolated-pol-dc-converter-module-246-w-600-mv
**SKU**: RPZ-0.6-CT
**Manufacturer**: RECOM POWER
**Category**: Power & Line Protection || Power Supplies || DC / DC Converters || DC / DC Non Isolated Board Mount Converters - Adjustable Output
**Price**: β¬1.7800
**Stock**: 10+
## Specifications
| Parameter | Value |
|---|---|
| Svhc | No SVHC (25-Jun-2020) |
| Depth | 2mm |
| Width | 1.5mm |
| Height | 1mm |
| Product Range | RPZ-0.6 Series |
| Output Power Max | 2.46W |
| Output Current Max | 600mA |
| Output Voltage Max | 4.1V |
| Output Voltage Min | 600mV |
| Input Voltage Dc Max | 5.5V |
| Input Voltage Dc Min | 1.8V |
| Dc / Dc Converter Type | Module |
| Power Supply Applications | - |
| Dc / Dc Converter Output Type | Adjustable |
## Datasheet
π [Download PDF](https://novapart.co/datasheet/farnell:4079812/)
## Features β’ 1.8 - 5.5VDC input 0.6A buck regulator module β’ Integrated inductor **DC/DC Converter** β’ Low profile 1mm Power β’ Small footprint 2x1.5mm β’ Adjustable output 0.6 to 4.1VDC Module β’ Up to 125Β°C ambient temperature with derating **RPZ-0.6** ee ~~β_~~ Description **0.6 Amp** NEAR The RPZ-0.6 is a 0.6A buck converter with integrated power transistors and inductor in a tiny **3** 2mm x 1.5mm x 1mm thermally-enhanced QFN package. The input range is from 1.8 to 5.5VDC **8-Pin QFN** arrasy for use in low power/low voltage systems. The tightly regulated output voltage can be set with two resistors in the range from 0.6V up to 4.1V. The output current is up to 0.6A and is fully protected **Package**
The RPZ-0.6 is a 0.6A buck converter with integrated power transistors and inductor in a tiny 2mm x 1.5mm x 1mm thermally-enhanced QFN package. The input range is from 1.8 to 5.5VDC for use in low power/low voltage systems. The tightly regulated output voltage can be set with two resistors in the range from 0.6V up to 4.1V. The output current is up to 0.6A and is fully protected against continuous short-circuits, output overcurrent or over-temperature faults. Its high current and small size make the RPZ-0.6 ideal for optical modules, industrial PCs, machine imaging systems, distributed power architectures, portable equipment in telecom as well as industrial applications.
**==> picture [490 x 473] intentionally omitted <==**
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Selection Guide
Part Input Output Output Efficiency [(2)]
Number Voltage Range Voltage Range [ (1)] Current max. typ.
[VDC] [VDC] [mA] [%]
RPZ-0.6 1.8 - 5.5 0.6 - 4.1 600 90
RoHS 2+ REACH
Notes: compliant10 from 10 compliant
Note1: As input approaches output voltage set point, device enters 100% duty cycle mode. In 100% duty
cycle mode, Vout equals Vin minus dropout voltage. (refer to βSAFE OPERATING AREAβ
Note2: Efficiency tested at VIN= 4.5VDC, full load, and VOUT= 3.3VDC
Model Numbering
RPZ-0.6-__
Output Current Packaging [ (3)]
Notes:
Note3: add suffix β-Rβ for tape and reel packaging
add suffix β-CTβ for cut tape packaging (refer to β βPACKAGING INFORMATIONβ )
Specifications
ABSOLUTE MAX RATINGS (exceeding these ratings may damage the device)
Parameter Symbol Min. Typ. Max.
VIN, VOUT, SW 6VDC
Absolute Maximum Voltage
others [(4)] 6.6VDC
Maximum continuous power losses [(5)] TAMB = 25Β°C 0.4W
Junction Temperature TJ -40Β°C +150Β°C
Lead Temperature 10 seconds max +260Β°C
Notes:
Note4: For CTRL absolute max ratings, please refer to βCTRL Operating CONDITIONSβ
Note5: Exceeding maximum allowable power dissipation causes device to enter thermal shutdown
which protects device from permanent damage. Refer to βCHARACTERISTIC CURVESβ
T T
ON ON
N P N P
C C V
R
V
A R A
E
O
E
I O I
M M
L L
R R
P D P D
O T O T
U U
C C
M M
E E
C C
E R E R
O T O T
R R S
S
S
C S C
**----- End of picture text -----**
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## **RPZ-0.6**
## **DC/DC Converter**
## **Series**
## Specifications
**==> picture [526 x 374] intentionally omitted <==**
**----- Start of picture text -----**
OPERATING CONDITIONS (VIN= 4.2VDC, VOUT= 1.8VDC, IOUT= 0.6A, unless otherwise noted, typical values are at TAMB= +25Β°C)
Parameter Symbol Condition Min. Typ. Max.
Input Voltage Range VIN refer to βSAFE OPERATING AREAβ 1.8VDC 5.5VDC
Under Voltage Lockout UVLO 1.8VDC
UVLO hysteresis 100mV
Output Voltage Range VOUT refer to βOUTPUT VOLTAGE SETTINGβ 0.6VDC 5.5VDC
Output Current Range IOUT 0A 0.6A
Standby current IIN VCTRL = 0VDC 0.1Β΅A 1Β΅A
Quiescent current IQ VFB = VREF x 105% 4Β΅A
Switching frequency fSW 3MHz
Feedback voltage VFB 588mV 600mV 612mV
Output load regulation refer to βCharacteristic Curvesβ
Maximum Duty Cycle 100%
Minimum On Time 80ns
Soft Start 1ms
Typical Application
VIN= 1.8-5.5VDC, VOUT= 1.8VDC, IOUT= 0.6A
VIN VIN VOUT Vout
4.7Β΅FCIN (6) RPZ-0.6 R1 CFF(7) 10Β΅FCOUT(6)
1M β¦ 100pF
VCTRL CTRL FB
ON/OFF
R2
SW 499k β¦
GND
**----- End of picture text -----**
Notes:
- Note6: The RPZ-0.6 require a 4.7Β΅F MLCC input capacitor as close as possible to VIN and GND pin and a 10Β΅F output capacitor to reduce noise. When VOUT <1.2VDC a minimum 20Β΅F output capacitor is recommended.
**==> picture [503 x 9] intentionally omitted <==**
**----- Start of picture text -----**
Note7: Transient load reaction time can be improved by adding a feed-forward capacitor, CFF across VOUT and FB pin, but it is not required for normal operation.
**----- End of picture text -----**
## SAFE OPERATING AREA
**==> picture [220 x 192] intentionally omitted <==**
**----- Start of picture text -----**
6
5.5
5
4
3
2
1.8
1
0
0 0.5 1.0 1.5 2 2.5 3 3.5 4
0.6 4.1
Output Voltage [VDC]
Input Voltage [VDC]
**----- End of picture text -----**
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## **RPZ-0.6**
## **DC/DC Converter**
## **Series**
## Specifications
## OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC. The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1M Ξ© . Use the equation to calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specified voltage may slightly vary.
## Feedback Network
VOUT VOUT Table below lists recommended resistor values for common VOUT: Calculation: VOUTset [VDC] R1 [ Ξ© ] R2 [ Ξ© ] CFF [pF][*] COUT [Β΅F] CFF R1 1.2 1M 20 FB πΉπΉπΉπΉππππ = (πππππππππππ0.6ππππβ0.6ππππ) Γ π
π
π
π
1 1.51.8 1M 665k499k 22-100 1010 R2 2.5 316k (optional *) 10 3.3 221k 10 Practical example with VOUTset= 1.8VDC *to stabilize the system and optimize the load transient response, place a feed-forward capacitor (CFF) in parallel with R1. 0.6ππππ πΉπΉπΉπΉππππ = (1.8ππππβ0.6ππππ) Γ 1ππππβ¦= ππππππβ¦
|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|OUTPUT VOLTAGE SETTING
A resistor divider connected to the FB pin (pin 4) sets the output voltage of the RPZ-0.6. The output voltage adjustment range is from 0.6VDC to 5.5VDC.
The schematic below shows the feedback resistor connections for setting the output voltage. The recommended value of R1 is 1MΞ©. Use the equation to
calculate the value for R2. The table below lists the R2 resistor values according to standard E96 values; therefore, the specifed voltage may slightly vary.
Table below lists recommended resistor values for common VOUT:
Feedback Network
Calculation:
R1
CFF
R2
FB
VOUT
VOUT
VOUTset[VDC]
R1 [Ξ©]
R2 [Ξ©]
CFF[pF]*
COUT[Β΅F]
1.2
1M
1M
22-100
(optional *)
20
1.5
665k
10
1.8
499k
10
2.5
316k
10
3.3
221k
10
πΉπ=
0.6π
(ππππβ0.6π)
Γ π
1
πΉπ=
0.6π
(1.8πβ0.6π)
Γ 1πβ¦= ππβ¦
Practical example with VOUTset= 1.8VDC
*to stabilize the system and optimize the load transient response,
place a feed-forward capacitor (CFF) in parallel with R1.
nary|
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
|CTRL OPERATING CONDITIONS(VIN= 4.2VDC, VOUT= 1.8VDC, IOUT= 0.6A, unless otherwise noted, typical values are at TAMB= +25Β°C)
|||||||||||||||
|Parameter
||Symbol
|||Condition
||Min.
||||Typ.
||Max.
||
|CTRL risingthreshold
||VCTRL_RISING
|||||1.2VDC
||||||||
|CTRL fallingthreshold
||VCTRL_FALLING
|||||||||||0.4VDC
||
|CTRL hysteresis
|||||||||||100mV
||||
||||||||||||||||
|PROTECTIONS
|||||||||||||||
|Parameter
||||Condition
||||Value
|||||||
|Short Circuit Protection SCP
||||||||hiccupmode
|||||||
|Over Current Protection OCP
||||||||1.3A typ.
|||||||
|Thermal shutdown
||||junction temperature
||||150Β°C typ.
|||||||
|||||hysteresis
||||15Β°C
|||||||
||||||||||||||||
|THERMAL OPERATING CONDITIONS(VIN=
||||4.2VDC, VOUT= 1.8VDC, IOUT= 0.6A, unless otherwise noted, typical values are at TAMB= +25Β°C)
|||||||||||
|Parameter
||Symbol
||||Condition
|||Min.
|||Typ.
||Max.
|
|OperatingAmbient Temperature
||TAMB
||||junction to ambient
|||refer to_βThermal Deratingβ_
||||||
|OperatingJunction Temperature
||TJ
|||||||-40Β°C
|||||+125Β°C
|
|Thermal Resistance(8)
||RthJA
||||junction to ambient
||||||60.3K/W
|||
|||RthJC
||||junction to case
||||||10K/W
|||
||Notes:
||||||||||||||
||||||||||||||||
|ENVIRONMENTAL|||||||||||||||
|Parameter|||Condition|||||||Value|||||
|ESD|||human-bodymodel(HBM), ANSI/ESDA/JEDEC JS-001|||||||Β±2.5kV|||||
||||charged-device model(CDM), JEDEC JESD22-C101|||||||Β±600V|||||
|MTTF|||TJ= 55Β°C; VIN= 5.5VDC|||||||13100 x 10Β³ hours|||||
REV.: 0/2022
I-3
**www.recom-power.com**
## **RPZ-0.6**
## **DC/DC Converter**
## **Series**
## Specifications
TYPICAL PERFORMANCE CHARACTERISTICS (VOUT= 1.8VDC, TJ= +25Β°C; tested with RECOM evaluation module: RPZ-0.6-EVM-1)
**==> picture [588 x 663] intentionally omitted <==**
**----- Start of picture text -----**
Characteristic Curves
Efficiency vs. Output current Thermal Derating
100 100
90 90
80 80
70 70
60 60
50 50
40 40
30 2.5Vin 30
3.3Vin
20 20
5.0Vin
1.8-5.5Vin
10 5.5Vin 10
0 0
0 10 20 30 40 50 60 70 80 90 100 -40 -30 -20 -10 0 20 40 60 80 100 120 140
125
Output Load [%] Ambient Temperature [Β°C]
Deviation vs. Load Power Dissipation
2.5 0.3
2.5Vin
2.0
3.3Vin 0.25
1.5 5.0Vin
5.5Vin
1.0 0.2
0.5
0.15
0
-0.5 0.1 2.5Vin
-1.0 3.3Vin
0.05 5.0Vin
-1.5 5.5Vin
-2.0 0
0 10 20 30 40 50 60 70 80 90 100 0 10 20 30 40 50 60 70 80 90 100
Output Load [%] Output Load [%]
TYPICAL PERFORMANCE CHARACTERISTICS (VOUT= 3.3VDC, TJ= +25Β°C; tested with RECOM evaluation module: RPZ-0.6-EVM-1)
Efficiency vs. Output current Thermal Derating
100 100
90 90
80 80
70 70
60 60
50 50
40 40
30 4.2Vin 30
4.5Vin
20 20
5.0Vin 4.2-5.5Vin
10 5.5Vin 10
0 0
0 10 20 30 40 50 60 70 80 90 100 -40 -30 -20 -10 0 20 40 60 80 100 120 140
125
Output Load [%] Ambient Temperature [Β°C]
continued on next page
Preliminary
Efficiency [%]
Output Load [%]
Deviation [%]
Power Dissipation [W]
Efficiency [%]
Output Load [%]
**----- End of picture text -----**
REV.: 0/2022
I-4
**www.recom-power.com**
## **RPZ-0.6**
## **DC/DC Converter**
## **Series**
## Specifications
**==> picture [588 x 687] intentionally omitted <==**
**----- Start of picture text -----**
TYPICAL PERFORMANCE CHARACTERISTICS (VOUT= 3.3VDC, TJ= +25Β°C; tested with RECOM evaluation module: RPZ-0.6-EVM-1)
Deviation vs. Load Power Dissipation
4.5 0.3
4.2Vin
4.0
4.5Vin 0.25
5.0Vin
3.5
5.5Vin
0.2
3.0
2.5 0.15
2.0
0.1
4.2Vin
1.5 4.5Vin
0.05 5.0Vin
1.0
5.5Vin
0.5 0
0 10 20 30 40 50 60 70 80 90 100 0 10 20 30 40 50 60 70 80 90 100
Output Load [%] Output Load [%]
DIMENSION AND PHYSICAL CHARACTERISTICS
Parameter Type Value
Dimension (LxWxH) 2.0 x 1.5 x 1.0mm
Weight 0.1g typ.
Dimension Drawing (mm)
2.0 [Β±0.1]
Pad Information
Top View
Pad # Function Description
Output voltage pin. Decouple this pin to GND with at least a 10Β΅F MLCC
1 VOUT (refer to βTypical Applicationβ )
2 CTRL Pull high to turn on. Don not leave floating.
PIN 1 ID 3, 7 GND Ground pin
Index Area
Feedback voltage pin. Connect to the center point of output resistor divider
4 FB
to set the output voltage. (refer to βOUTPUT VOLTAGE SETTINGβ
5, 6 SW Switch node pin. Leave it floating
Side View
Input voltage pin. Decouple to GND with at least a 4.7Β΅F ceramic capacitor
8 VIN (refer to βTypical Applicationβ )
All dimensions exclude mold flash and metal burr. Tolerances:
x.x= Β±0.1mm
x.xx= Β±0.05mm
Recommended Footprint Details [(*)]
(Top View)
Bottom View
0.15 0.20
0.2 [Β±0.05] 0.4 0.4
8 7 6
2 3 4
PKG PKG 1 5
1 5
8 7 6 2 3 4
0.40 0.35
PKG
PKG
2.00
* A large ground plane greatly reduces noise and increases thermal performance.
Preliminary
Deviation [%]
Power Dissipation [W]
Β±0.1
1.5
Β±0.15
0.09-0.28
0-0.05
0.85
Β±0.050.5 0-0.1
Β±0.1 1.70 1.00
.40 0.8 0.70
**----- End of picture text -----**
REV.: 0/2022
I-5
**www.recom-power.com**
## **RPZ-0.6**
## **DC/DC Converter**
## **Series**
## Specifications
SAFETY AND CERTIFICATIONS Certificate Type (Safety) Standard RoHS2 RoHS 2011/65/EU + AM2015/863
Standard
## SOLDERING
**==> picture [506 x 257] intentionally omitted <==**
**----- Start of picture text -----**
Profile Feature PB-Free 1 Pb-Free assembly is recommended according ro JEDEC J-STD020.
Assembly 2 Ensure that the peak re-flow temperature does not exceed 240Β°C Β±5Β°C as
Preheat per JEDEC J-STD020
minimum Temperature (TS_min) 150Β°C 3 The re-flow time period during peak temperature of 240Β°C Β±5Β°C should not
exceed 30 seconds.
maximum Temperature (TS_max) 200Β°C
4 Re-flow time above liquids (217Β°C) should not exceed 150 seconds.
Time (tS) 60s-120s
5 For solder paste use a standard SAC Alloy such as SAC 305, type 3 or higher.
6 Other soldering methods (e.g. vapor-phase) are not verified and have to be
Liquids
validated at his own risk.
Temperature (TL) 217Β°C
Time (tL) 60-150s Solder Pofil
Ramp up Rate: 3Β°C/s
Peak Temp.: 250-255Β°C
Peak Temperature (TP) 255Β°C 300 Melting Time: 60-150s
217Β°C
217Β°C
max Ramp Down Rate (from Ts_max to TP) 6Β°C/s 200 200Β°C
max Ramp Up Rate 3Β°C/s 150Β°C
max time from 25Β°C to Peak Temperature (TP) 8min 100 PREHEAT ZONE HEATINGACTUAL COOLING
00 100 200 300
Time [s]
Preheat Temp.: 150-200Β°C Ramp Down Rate: 6Β°C/s
Temperature [Β°C]
**----- End of picture text -----**
|max time from 25Β°C to Peak Temperature (TP)
|max time from 25Β°C to Peak Temperature (TP)
|00
100
300
200
100
Time [s]
Tem
Ramp Down Rate: 6Β°C/s
Preheat Temp.: 150-200Β°C
PREHEAT ZONE
COOLING
U
HEATING
8min
im|00
100
300
200
100
Time [s]
Tem
Ramp Down Rate: 6Β°C/s
Preheat Temp.: 150-200Β°C
PREHEAT ZONE
COOLING
U
HEATING
8min
im|
|---|---|---|---|
|PACKAGING INFORMATION
||||
|Parameter
||Type
|Value
|
|Packaging Dimension (LxWxH)
||reel 7β(diameter + width)
|Γ177.8 + 8.4mm
|
|||tape and reel(carton)
|215.0 x 215.0 x 215.0mm
|
|||moisture barrier bag (β-CTβ)
|100.0 x 100.0 x 30.0mm
|
|Packaging Quantity
||tape and reel
|3000pcs
|
|||moisture barrier bag (β-CTβ)
|50pcs
|
|Tape Width
|||8mm
|
|Storage Temperature Range
|||-55Β°C to +150Β°C
|
|Moisture Sensitive Level
||MSLpeak temp.(9)
|Level 3, 260Β°C, 168hrs
|
||Notes:
|||
|||||
The product information and specifications may be subject to changes even without prior written notice.The product has been designed for various applications; its suitability lies in the responsibility of each customer. The products are not authorized for use in safety-critical applications without RECOMβs explicit written consent. A safety-critical application is an application where a failure may reasonably be expected to endanger or cause loss of life, inflict bodily harm or damage property. The applicant shall indemnify and hold harmless RECOM, its affiliated companies and its representatives against any damage claims in connection with the unauthorized use of RECOM products in such safety-critical applications.
REV.: 0/2022
I-6
**www.recom-power.com**
## Links
- [View this product on Novapart](https://novapart.co/products/RPZ-0.6-CT/non-isolated-pol-dc-converter-module-246-w-600-mv)
- [Request a quote for this part](https://novapart.co/quote/)
- [Supplier page](https://es.farnell.com/recom-power/rpz-0-6-ct/dc-dc-converter-0-6v-to-4-1v-0/dp/4079812)
---
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